Computer-implemented method and system for binding digital rights management executable code to a software application

ABSTRACT

A computer-implemented method and system for binding digital rights management executable code to a software application are disclosed. The method and system include selecting a memory page of host application code, translating the contents of the selected memory page of host application code, saving the translated contents of the selected memory page into a stub code area, overwriting the selected memory page of host application code; removing host page permission for execution of code in the selected memory page of host application code, and emulating the translated contents of the selected memory page when an exception is raised as a result of attempted access to the selected memory page of host application code.

RELATED PATENT APPLICATION

This patent application is a continuation-in-part of co-pending patent application, Ser. No. 11/598,318 filed Nov. 13, 2006; entitled, “A COMPUTER-IMPLEMENTED METHOD AND SYSTEM FOR BINDING DIGITAL RIGHTS MANAGEMENT EXECUTABLE CODE TO A SOFTWARE APPLICATION”; which claims the priority benefit of EPO application no. 06380096.3 filed Apr. 26, 2006 entitled, “A COMPUTER-IMPLEMENTED METHOD AND SYSTEM FOR BINDING DIGITAL RIGHTS MANAGEMENT EXECUTABLE CODE TO A SOFTWARE APPLICATION, all of which are incorporated herein by reference.

BACKGROUND

1. Technical Field

This disclosure relates to digital rights management methods and systems. More particularly, the present disclosure relates to binding digital rights management executable code to a software application.

2. Related Art

The advent of digital distribution has created new business models for the delivery of software over the internet. One of the most widely used techniques to provide protection against illegal distribution and piracy of software is called wrapping.

Wrapping consists of adding a security and verification layer or a digital rights management layer (wrapper code) on top of an unprotected executable (host software or wrapped code henceforward) that typically verifies its associated business rules. Business rules typically include verification that the protected software has been purchased or, in the case of try and buy offerings, verification that the software is still within the trial period. Other types of digital rights management technologies can similarly be used. The most obvious benefit of performing wrapping at the executable level (vs. implementing security at the source-code level) is that the software developer does not need to worry about security when designing or implementing his or her software as wrapping does not require any source-code modifications. This results in a faster time to market.

The wrapper code (stub henceforward) verifies that a set of conditions are met when the protected executable first starts and then allows it to run normally if everything is as expected. For example, in a try-before-you-buy scenario, the wrapping code might first check the current date. If the current date is greater than the trial period's end, the software will display an expiration screen. Conversely, if the software is allowed to run, the wrapped code will be unencrypted and executed. At the moment when the host software is unencrypted, the software is vulnerable.

One of the most common attacks against wrapped software is to regenerate the original executable from the wrapped (or protected) executable. Because the original, non-secured executable contains no protection logic, it is relatively easy to dump the host software from memory and then distribute the unprotected host code throughout the Internet and Peer-to-Peer networks. This attack technique is possible because in conventional wrapping, the original wrapped executable can be easily separated from the wrapper code.

Current software production models join a wrapper (stub) to the application to be protected (host) during a preparation phase. When a protected application is launched, the stub enables the host to run (usually the application is encrypted or mangled to make it difficult to run without running the stub code first). The stub code is high secure code, while the host code is typically insecure code that could be easily modified by experts.

When host code is protected with any of the existing protection models, the easiest attack is the “memory dump attack”. A memory dump attack is performed by waiting until the stub code is executed, and then the memory area occupied by the executable (including the protected application) is dumped to disk or other storage medium. This memory area is a plain image of the protected application that could be modified to allow the operating system loader to launch the modified protected application again without running the stub code. In this manner, the protection of the protected application is effectively circumvented.

To prevent this attack, the protection model must mangle, in some way, the host code and maintain the host code in a mangled state, while the host code resides in memory. When a mangled area of host code is reached, the stub code will be responsible for managing the execution flow. By mangling the host code, the attacker is forced to recompose the mangled host code bytes to allow the application to run without assistance from the stub. Because the host requires the execution of the stub code, this conventional protection system enables the execution of additional anti-tampering routines as part of the overall protection system. However, these anti-tampering routines are never executed if the attacker is able to strip out the stub code and execute the host code directly.

Thus, a computer-implemented method and system for binding digital rights management executable code to a software application are needed.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments illustrated by way of example and not limitation in the figures of the accompanying drawings, in which:

FIG. 1 depicts the usual flow for wrapped software.

FIGS. 2A and 2B illustrate an embodiment of the improved wrapping process.

FIGS. 3A and 3B illustrate an embodiment of the improved wrapping process where the host code block is retained.

FIGS. 4A and 4B illustrate an embodiment of the improved wrapping process where a security block is provided.

FIGS. 5A and 5B illustrate an embodiment of the improved wrapping process where the stub code is transformed.

FIGS. 6-9 are flow diagrams illustrating the processing steps in various embodiments.

FIGS. 10 a and 10 b are block diagrams of a computing system on which an embodiment may operate and in which embodiments may reside.

FIG. 11 illustrates an example of a function that has an entry point in the middle of the function, which may not be guaranteed to be found by a disassembler.

FIG. 12 illustrates a page-partitioned host application code segment and a corresponding portion of stub code of an example embodiment of the protection system described herein.

FIG. 13 illustrates the emulation of the protected host code.

FIGS. 14 and 15 are flow diagrams illustrating examples of the processing flow of various embodiments.

DETAILED DESCRIPTION

A computer-implemented method and system for binding digital rights management executable code to a software application are disclosed. In the following description, numerous specific details are set forth. However, it is understood that embodiments may be practiced without these specific details. In other instances, well-known processes, structures and techniques have not been shown in detail in order not to obscure the clarity of this description.

Various embodiments include a mechanism to bind digital rights management executable code to an application (host software) without requiring code changes to the application. Some of the application blocks are copied to the code section where the digital rights management code resides, making removal of the digital rights management code more difficult to automate. As used herein, a code section (e.g. a host code section or a stub code section) simply refers to a contiguous block of code and does not mean to imply the use of particular data or code structures provided or defined by a particular software or operating system developer.

Various embodiments strive to improve the binding between the host executable and the stub code while maintaining the benefit of not requiring modifications of the host at the source-code level.

FIG. 1 depicts the usual flow for wrapped software. Block 110 represents a software component, including an encrypted executable code portion 112 and a wrapping code portion 114. Executable code 112 can be host application software typically developed by a third party software developer and/or distributor. Wrapping code 114 comprises security or validation software, or software for enforcing digital rights management policies in relation to executable code 112. Software component 110 is typically made available for purchase or license by end-users through various distribution means such as network downloads or software available on computer readable media. Once an end-user obtains software component 110, the user can activate the software using conventional means. Upon activation, execution of a software component 110 begins at a location within wrapping code 114 as shown by arrow 140 in FIG. 1. Wrapping code 114 can execute various business rules and/or digital rights management rules, such as try-before-you-buy policies. For example, based upon a particular set of rules and associated conditions, wrapping code 114 may determine that a particular user may be allowed to access and use executable code 112 as purchased software or trial software. In this case, path 150 is taken as shown in FIG. 1 to a different portion of wrapping code 124. The different portion of wrapping code 124 decrypts executable code 112 to produce unencrypted executable code 122. Wrapping code 124 then jumps to the unencrypted executable code 122 as shown by path 152 and the user is then able to use host application software 122. Conversely, if wrapping code 114 determines that the user is not allowed to access executable code 112, path 154 is taken to another portion of wrapping code 134, where wrapping code 134 halts execution and shows the user an informational message indicating that access to executable code 112 is not allowed. In this manner, conventional wrappers can be used to protect a related executable code component.

Various embodiments improve conventional wrapping by more tightly binding the wrapping code (stub) to the wrapped executable code (host code) to be protected. In one embodiment, the improved wrapping process consists of identifying blocks within the host code that can be moved across the boundary between the executable code and the wrapper. This process involves picking a block of code from the stub whose size is equal or less than the host block, copying the host block to the memory section of the stub, adjusting inbound and outbound memory references to and from the host block to other blocks or locations within the host, copying the stub block to the memory section of the host, and adjusting inbound and outbound memory references to and from the host block to other blocks or locations within the stub.

The identification of host blocks can be done using conventional code disassemblers as well known to those of ordinary skill in the art. There are commercial programs such as IDA Pro (www.datarescue.com) that provide tools for the disassembling of executable code for multiple processors. These conventional code disassembly techniques can be automated using various methods.

FIG. 2A illustrates an example of one host executable 250 in which a host block 252 has been identified at offset 0x40A4C7. Block 252 of the host code contains one outbound reference 254 (a call to location 0x40A4D0) and two inbound references 256 and 258 (from locations 0x4080A0 and 0x40D012, respectively). FIG. 2B shows the final executable 260 produced as a result of various embodiments. In executable 260, host block 252 has been moved to the stub code section 261 at location 262 and the inbound and outbound references have been corrected accordingly. In particular, outbound reference 254 has been re-routed as outbound reference 264. Inbound reference 256 has been re-routed as inbound reference 266. Inbound reference 258 has been re-routed as inbound reference 268. The host code block at location 265 (same location as block 252) has been overwritten with random instructions.

Referring to FIG. 6, a flow diagram illustrates the processing steps performed in one embodiment. At processing block 612, a host code block in the host code section is identified. At processing block 614, a copy of the host code block is written to a stub code block in the stub code section. At processing block 616, at least one reference of the host code block is re-routed to be a reference of the stub code block. In various embodiments, outbound and inbound references are corrected in the manner described above.

In some circumstances not all of the inbound references to host blocks can be reliably determined. The following embodiment deals with this circumstance. In another embodiment, the improved wrapping process consists of identifying blocks within the host code that can be moved across the boundary between the executable code and the wrapper. This process involves copying the host block to the memory section of the stub and adjusting inbound and outbound memory references to and from the host block to other blocks or locations within the host.

FIG. 3A illustrates an example of one host executable 350 in which a host block 352 has been identified at offset 0x40A4C7. Block 352 the host code contains one outbound reference 354 (a call to location 0x40A4D0) and two inbound references 356 and 358 (at locations 0x4080A0 and 0x40D012, respectively). In addition, there is an unknown reference 359 to location 0x40A4C7 depicted with a dashed line. FIG. 3B shows the final executable 360 produced as a result of various embodiments. In executable 360, a copy of host block 352 has been moved to the stub code section 361 at location 362 and the inbound and outbound references have been corrected accordingly. In particular, outbound reference 354 has been re-routed as outbound reference 364. Inbound reference 356 has been re-routed as inbound reference 366. Inbound reference 358 has been re-routed as inbound reference 368. Additionally, the original copy of the host block 352 has been left in the original location 365 within the host code, so the unknown reference 369 to location 0x40A4C7 continues to render consistent results as the reference 359 in the original copy of the host block 352 that remains at location 0x40A4C7.

Referring to FIG. 7, a flow diagram illustrates the processing steps performed in one embodiment. At processing block 712, a host code block in the host code section is identified. At processing block 714, a copy of the host code block is written to a stub code block in the stub code section. At processing block 716, at least one reference of the host code block is re-routed to be a reference of the stub code block. In various embodiments, outbound and inbound references are corrected in the manner described above. At processing block 718, at least one reference of the host code block is retained to remain a reference of the host code block.

To further improve the binding between the host code and the stub code, another embodiment consists of identifying blocks within the host code that can be moved across the boundary between the executable code and the wrapper. This process involves, copying an identified host block to the memory section of the stub, adjusting outbound memory references from the host block to other blocks or locations within the host, and pointing the inbound blocks to a stub routine that performs security checks, such as CRC verifications, debugger detections, optical disc signature verifications (e.g. U.S. Pat. Nos. 6,535,469; 6,748,079; 6,560,176; 6,928,040; 6,425,098; 6,952,479; 6,029,259; and 6,104,679), checking the authenticity of a BIOS in a console system, checking the presence of a mod-chip in a console system, and other tamper-proofing verifications known to those of ordinary skill in the art.

FIG. 4A illustrates an example of one host executable 450 in which a host block 452 has been identified at offset 0x40A4C7. Block 452 of the host code contains one outbound reference 454 (a call to location 0x40A4D0) and two inbound references 456 and 458 (at locations 0x4080A0 and 0x40D012, respectively). FIG. 4B shows the final executable 460 produced as a result of various embodiments. In executable 460, host block 452 has been moved to the stub code section 461 at location 462 and outbound references have been corrected accordingly. In particular, outbound reference 454 has been re-routed as outbound reference 464. The inbound references 456 and 458 to host block 452 have been re-routed to a stub routine 463 contained within the stub code section 461 and located at offset 0x490010 as shown in FIG. 4B as location 463. The host code block at location 465 (same location as block 452) has been overwritten with random instructions. As described above, stub routine 463 can be any of a variety of security, authorization, verification, digital rights management, access control, and/or tamper-proofing routines that can be executed prior to or after enabling access to the host code. Inbound reference 456 has been re-routed to stub routine 463 as inbound reference 466. Inbound reference 458 has been re-routed to stub routine 463 as inbound reference 468. When stub routine 463 has completed execution, processing control is transferred back from stub routine 463 to the copy of host block 462 at location 0x481A25 on path 469. At this point, the stub code section 461 has completed a desired level of security and/or access checking by virtue of the execution of stub routine 463.

Referring to FIG. 8, a flow diagram illustrates the processing steps performed in one embodiment. At processing block 812, a host code block in the host code section is identified. At processing block 814, a copy of the host code block is written to a stub code block in the stub code section. At processing block 816, a stub routine is provided in the stub code section. As described above, the stub routine can be any of the security, authorization, verification, digital rights management, access control, and/or tamper-proofing routines described above. At processing block 818, at least one reference of the host code block is re-routed to be a reference of the stub routine. At processing block 820, at least one reference of the stub routine is re-routed to be a reference of the stub code block. In various embodiments, outbound and inbound references are corrected in the manner described above.

One potential attack that an attacker could use to determine if a given function in the stub code section is actually a function copied from the host code would be to find all memory references from the host to the stub section and determine if the corresponding memory in the stub section can be found in the host code. If this copy of the host code is found in the stub code, the attacker could replace the pointer to the stub code with the location of the corresponding pointer in the host code. This would effectively sever the wrapper code from the host code. To hamper this attack, another embodiment transforms the host function that is copied from the host code to the stub code by transforming the code to a functionally equivalent but not readily discernable form. One embodiment of code transformation is obfuscating the host function code at the assembly language level. For example, U.S. Pat. No. 6,591,415 describes how to obfuscate functions at the assembly code level. It will be apparent to those of ordinary skill in the art that other forms of code transformation could similarly be used.

FIG. 5A illustrates an example of one host executable 550 in which a host block 552 has been identified at offset 0x40A4C7. Block 552 of the host code contains one outbound reference 554 (a call to location 0x40A4D0) and two inbound references 556 and 558 (at locations 0x4080A0 and 0x40D012, respectively). FIG. 5B shows the final executable 560 produced as a result of various embodiments. In executable 560, host block 552 has been moved to the stub code section 561 at location 562 and outbound references have been corrected accordingly. In particular, outbound reference 554 has been re-routed as outbound reference 564. The inbound references 556 and 558 to host block 552 have been re-routed to a stub routine 563 contained within the stub code section 561 and located at offset 0x490010 as shown in FIG. 5B as location 563. The host code block at location 565 (same location as block 552) has been overwritten with random instructions. As described above, stub routine 563 can be any of a variety of security, authorization, verification, digital rights management, access control, and/or tamper-proofing routines that can be executed prior to or after enabling access to the host code. Inbound reference 556 has been re-routed to stub routine 563 as inbound reference 566. Inbound reference 558 has been re-routed to stub routine 563 as inbound reference 568. When stub routine 563 has completed execution, processing control is transferred back from stub routine 563 to the copy of host block 562 at location 0x481A25 on path 569. At this point, the stub code section 561 has completed a desired level of security and/or access checking by virtue of the execution of stub routine 563. As an additional defense against potential hackers, the copy of host block 552 has been code transformed (e.g. obfuscated) using conventional techniques and the transformed code has been moved to the stub code section 561 at location 562. The outbound references have been corrected accordingly. As described above, the inbound references have been re-directed to the stub routine 563 contained within the stub code section 561. The transformed host block 562 is difficult for potential attackers to find and detach or disable from the host code.

Referring to FIG. 9, a flow diagram illustrates the processing steps performed in one embodiment. At processing block 912, a host code block in the host code section is identified. At processing block 914, a copy of the host code block is written to a stub code block in the stub code section. At processing block 916, a stub routine is provided in the stub code section. As described above, the stub routine can be any of the security, authorization, verification, digital rights management, access control, and/or tamper-proofing routines described above. At processing block 918, at least one reference of the host code block is re-routed to be a reference of the stub routine. At processing block 920, at least one reference of the stub routine is re-routed to be a reference of the stub code block. In various embodiments, outbound and inbound references are corrected in the manner described above. At processing block 922, the stub code block is transformed (e.g. obfuscated).

Performing security checks, such as those executed by stub routine 563, can take a few milliseconds to be executed. In another embodiment, host functions are divided into two categories: 1) functions that are not performance sensitive and thus may contain security checks, and 2) functions that are performance sensitive and thus should not contain security checks. There are multiple methods of categorizing the host functions.

In one embodiment, performance-sensitive functions can be identified by having a pre-defined list of known performance-sensitive functions that a disassembler can readily identify. Run-time functions such as fclose, malloc, etc. that are statically linked to the host executable (and thus form the host executable) can be detected by commercial tools such as IDA Pro FLIRT.

In another embodiment, performance-sensitive functions can be identified by profiling the host executable and collecting information about function execution.

In another embodiment, performance-sensitive functions can be determined interactively prompting the user at wrapping time.

In many circumstances, it is advisable to decouple the security checks from their response in case the checks fail. Decoupling the security checks from their response makes it more difficult for attackers to disable the security checks or the responses

In another embodiment, the improved wrapping process consists of identifying blocks within the host code that can be moved across the boundary between the executable code and the wrapper. This process involves copying the host block to the memory section of the stub, adjusting outbound memory references from the host block to other blocks or locations within the host, and pointing the inbound blocks to a stub routine that performs security responses based on previously executed security checks. Such security responses may include showing messages to the end-user, shutting down the application, modifying registers or function return values, or any action that modifies the expected application behavior.

The embodiments described above can be used in conjunction with a digital signature that verifies the integrity of the executable as described in U.S. Pat. No. 6,802,006. It is also possible and advisable to combine elements from the various described embodiments to create more effective protection of the host executable.

FIGS. 10 a and 10 b show an example of a computer system 200 illustrating an exemplary client or server computer system in which the features of an example embodiment may be implemented. Computer system 200 is comprised of a bus or other communications means 214 and 216 for communicating information, and a processing means such as processor 220 coupled with bus 214 for processing information. Computer system 200 further comprises a random access memory (RAM) or other dynamic storage device 222 (commonly referred to as main memory), coupled to bus 214 for storing information and instructions to be executed by processor 220. Main memory 222 also may be used for storing temporary variables or other intermediate information during execution of instructions by processor 220. Computer system 200 also comprises a read only memory (ROM) and/or other static storage device 224 coupled to bus 214 for storing static information and instructions for processor 220.

An optional data storage device 228 such as a magnetic disk or optical disk and its corresponding drive may also be coupled to computer system 200 for storing information and instructions. Computer system 200 can also be coupled via bus 216 to a display device 204, such as a cathode ray tube (CRT) or a liquid crystal display (LCD), for displaying information to a computer user. For example, image, textual, video, or graphical depictions of information may be presented to the user on display device 204. Typically, an alphanumeric input device 208, including alphanumeric and other keys is coupled to bus 216 for communicating information and/or command selections to processor 220. Another type of user input device is cursor control device 206, such as a conventional mouse, trackball, or other type of cursor direction keys for communicating direction information and command selection to processor 220 and for controlling cursor movement on display 204.

A communication device 226 may also be coupled to bus 216 for accessing remote computers or servers, such as a web server, or other servers via the Internet, for example. The communication device 226 may include a modem, a network interface card, or other well-known interface devices, such as those used for interfacing with Ethernet, Token-ring, wireless, or other types of networks. In any event, in this manner, the computer system 200 may be coupled to a number of servers via a conventional network infrastructure.

The system of an example embodiment includes software, information processing hardware, and various processing steps, as described above. The features and process steps of example embodiments may be embodied in machine or computer executable instructions. The instructions can be used to cause a general purpose or special purpose processor, which is programmed with the instructions to perform the steps of an example embodiment. Alternatively, the features or steps may be performed by specific hardware components that contain hard-wired logic for performing the steps, or by any combination of programmed computer components and custom hardware components. While embodiments are described with reference to the Internet, the method and apparatus described herein is equally applicable to other network infrastructures or other data communications systems.

It should be noted that the methods described herein do not have to be executed in the order described, or in any particular order. Moreover, various activities described with respect to the methods identified herein can be executed in repetitive, simultaneous, recursive, serial, or parallel fashion. Information, including parameters, commands, operands, and other data, can be sent and received in the form of one or more carrier waves through communication device 226.

Upon reading and comprehending the content of this disclosure, one of ordinary skill in the art will understand the manner in which a software program can be launched from a computer-readable medium in a computer-based system to execute the functions defined in the software program described above. One of ordinary skill in the art will further understand the various programming languages that may be employed to create one or more software programs designed to implement and perform the methods disclosed herein. The programs may be structured in an object-orientated format using an object-oriented language such as Java, Smalltalk, or C++. Alternatively, the programs can be structured in a procedure-orientated format using a procedural language, such as assembly or C. The software components may communicate using any of a number of mechanisms well known to those of ordinary skill in the art, such as application program interfaces or inter-process communication techniques, including remote procedure calls. The teachings of various embodiments are not limited to any particular programming language or environment, including HTML and XML.

Thus, other embodiments may be realized. For example, FIGS. 10 a and 10 b illustrate block diagrams of an article of manufacture according to various embodiments, such as a computer 200, a memory system 222, 224, and 228, a magnetic or optical disk 212, some other storage device 228, and/or any type of electronic device or system. The article 200 may include a computer 202 (having one or more processors) coupled to a computer-readable medium 212, and/or a storage device 228 (e.g., fixed and/or removable storage media, including tangible memory having electrical, optical, or electromagnetic conductors) or a carrier wave through communication device 226, having associated information (e.g., computer program instructions and/or data), which when executed by the computer 202, causes the computer 202 to perform the methods described herein.

Various embodiments are described. In particular, the use of embodiments with various types and formats of user interface presentations may be described. It will be apparent to those of ordinary skill in the art that alternative embodiments of the implementations described herein can be employed and still fall within the scope of the claims set forth below. In the detail herein, various embodiments are described as implemented in computer-implemented processing logic denoted sometimes herein as the “Software”. As described above, however, the claimed invention is not limited to a purely software implementation.

Various embodiments described herein, enable the translation of an area of the host code into an emulated code, overriding the original bytes of this host code area, and emulating the execution of the instructions at the area when the execution flow falls into the protected area. If an attacker attempts to attack the protected application code by dumping the code to a memory area, the attacker must get back one or more large areas of the host code overwritten during the preparation phase. In most cases, the attacker will be unable to reconstruct the overwritten host code. Therefore, various embodiments prevent the successful attack of the host code.

A problem exists with some protection systems that perform code blending between the stub code and the host code. In some cases, it is not safe to erase host code if a given reference to the code block is unknown. Removal of arbitrary functions of host code may not be considered safe as references may be missed by a disassembler during protection of the host code. Even the most advanced disassemblers (e.g. IDA PRO) today can miss references to particular code segments when performing code disassembly.

As described above, one host code protection process includes moving code from the host code area to a stub code area. As described in further detail below, this process is extended to handle code blending situations where all entry points into a code segment cannot be completely determined. FIG. 11 illustrates an example of a function that has an entry point in the middle of the function, which may not be guaranteed to be found by a disassembler. As shown in FIG. 11, a standard function entry point 1110 is likely to be found by a disassembler; however, a jump instruction 112 that creates an entry point into the middle of the function is not likely to be found by a disassembler. In these and other situations, a better method is needed to blend host code and stub code without affecting the functionality of the code segment.

In general, to detect all entry points of a code block, it is necessary to, 1) disassemble the entire application, or 2) consider every possible instruction in the code block as a potential entry point. Those of ordinary skill in the art know that the first approach is not viable with generally available tools and remains an unsolved problem in reverse software engineering. Unfortunately, commercial software focused on disassembling code like IDA, is not able to disassemble every single instruction in a computer program. The second approach requires a mechanism that establishes for every minimal execution unit an entry point (typically an entry point for each byte or instruction). Readily available hardware features found in modern processors can help to establish a mechanism to make every possible instruction in a code block an entry point. Modern processors typically have a feature called pagination, which is designed to, 1) protect memory areas from unauthorized access (e.g., by other processes executing on the same processor); 2) load and store pages dynamically between memory and disk; and 3) detach data and code areas.

Some processors such as the x86 or x64 family (e.g. processors provided by Intel Corporation or AMD Corporation) allow the program to grant access permissions independently for every page. Prior to allowing execution of code in a protected page, the processor will raise an exception to signal an attempt to execute code in a protected page. In various embodiments described herein, this protected page access exception is captured and used to implement an emulation method for the protected memory area.

In various embodiments described herein, a host application in a host application area 1210 can be protected by performing the steps described below. FIG. 12 illustrates this part of the process. As shown in FIG. 12, a host application 1210 can be partitioned into a set of memory pages 1211 as supported by conventional processors as described above. First, one or more suitable memory pages of the host application code 1210 must be selected (see FIG. 14, processing block 1412). Every code page 1211 in the host application 1210 is a candidate to be a protected page. The most suitable pages to be protected are typically those that contain functions which are executed a minimal number of times. This is desirable, because if the page is accessed too often, system performance could be degraded. Further, it is desirable to choose a page which contains code that can be completely tokenized. The tokenization of a chosen page is performed prior to disassembly of a program or code block. In various embodiments, every instruction does not necessarily need to be recognized. However, it is important to be able to split the instructions as required. For this reason, a tokenizer is easier to implement than a disassembler. In the example of FIG. 12, a selected page 1213 of host application code 1210 is selected.

In a next step of an example embodiment of the process described herein, the content of the selected page or pages 1213 is translated and saved to a stub code area 1212 using a translator (see FIG. 14, processing block 1414). A translator is a software component that transforms the object code (e.g. assembler code for the target processor) into another code interpretable by an emulator. The translation could be as simple as interpreting the assembler code for the target processor from a different base address. However, the goal is to hide the code taken from the host to make it difficult for a hacker to reconstruct the original host application code. Those of ordinary skill in the art would know of many generally available interpreters and translators. For example, the Bochs IA32 emulator project provides a generally available x86 emulator. In addition, there are generally known tools and techniques to statically translate assembly code for one processor or architecture (e.g. x86, or x64) into another processor or architecture. For example, such translators can be found at www.softpear.org or www.itee.uq.edu.au. In the example of FIG. 12, the translated content of the selected page 1213 of host application code 1210 is saved in a corresponding page 1214 of stub code area 1212.

Once the selected host code page 1213 has been translated and saved to stub code page 1214, the selected host code page 1213 must be overwritten. In this step, the content of the host code memory page 1213 is overwritten or modified to prevent a hacker from using this portion of the host application 1210 (see FIG. 14, processing block 1416). It is possible to use any overwriting process (e.g., apply a constant bit pattern to the page, generate random code, etc.). When this portion of the step is finished, the host code can be merged with the stub code using generally available wrapping techniques, or the wrapping techniques described above.

Another step performed as part of the process described herein is performed during stub code execution. This step includes removing the host code memory page 1213 permissions for execution of host code in selected page 1213. Typically, the operating system provides functions to perform this step (e.g. Microsoft Windows provides the Win32 API function, “VirtualProtect” to allow the program to change the permissions for its pages). As a result of the removal of the host code memory page 1213 permissions for execution of host code in selected page 1213, the attempted access of selected page 1213 or attempted execution of host code formerly therein will trigger an exception, also called a page fault or page access exception.

A second part of an example embodiment of the process described herein is code emulation. As described above, when any instruction sends the execution flow to another instruction inside the protected area (e.g. a protected page 1213), an exception is raised. One component of the protection methods described herein is the exception handler. The exception raised as a result of an attempted access to protected page 1213 provides notice as to the address where the exception was produced. This address is typically the entry point to the protected code block. This allows the protection system to emulate the execution of the protected code block of instructions starting at a given address. FIG. 13 illustrates this part of the process.

As shown in FIGS. 12 and 13, the stub code 1212 must set an appropriate exception handler in order to, 1) capture an exception raised as a result of an attempted access to protected page 1213 and, 2) emulate the portion of the host application code 1210 in the selected protected host page or pages 1213 (see processing block 1512 of FIG. 15). As shown in FIG. 13, the execution of code 1310 has caused the attempted access to protected page 1312. As a result of the attempted access to protected page 1312, an exception or page fault is raised. Because the stub code 1212 had previously set up an exception handler to receive execution control when the exception or page fault is raised, stub exception handler 1314 is executed when the exception is raised as a result of an attempted access to protected page 1312. If the host application has the opportunity to define its own exception handler and potentially disabling the exception handler 1314 of the protection system, additional measures must be taken to prevent this disabling of the exception handler 1314 of the protected system.

Once the exception handler for the protected host code memory page is set up or pre-configured (see processing block 1512 of FIG. 15), the protection system of an example embodiment waits for an exception to be raised as a result of attempted access to the protected host memory page and the execution of the corresponding pre-configured exception handler to be triggered (see processing block 1514 of FIG. 15). When the stub exception handler 1314 catches the exception, the stub exception handler 1314 extracts the address and uses the address to trigger the execution of an emulator, which emulates the portion of the host code located in the protected host code memory page 1312 (see processing block 1516 of FIG. 15). The emulator can start at a given address inside the protected page and can finish when the instruction pointer points to a location outside the protected page. The emulator can be an interpreter that executes an encoded or translated version of the instructions copied from the selected host application memory page 1213. The emulator state (e.g. initialization tables, etc.) may be dependent on an authentication performed by a Digital Rights Management (DRM) subsystem. Typical authentication mechanisms include the presence of a valid security license, a physical token, and the like. By making the emulator depend on such authentication, the overall system is more secure as the protected host code cannot be executed unless the authentication has taken place and has been successful.

Thus, a computer-implemented method and system for binding digital rights management executable code to a software application are disclosed. While the present invention has been described in terms of several example embodiments, those of ordinary skill in the art will recognize that the present invention is not limited to the embodiments described, but can be practiced with modification and alteration within the spirit and scope of the appended claims. The description herein is thus to be regarded as illustrative instead of limiting. 

What is claimed is:
 1. A method comprising: selecting a memory page of host application code; translating executable code of the selected memory page of host application code; moving the translated executable code of the selected memory page from the host application into a stub code area comprising at least one stub routine for performing any of a security and access rights check; overwriting the selected memory page of host application code; removing host page permission for execution of code in the selected memory page of host application code; and emulating the translated executable code of the selected memory page that was moved into the stub code area when an exception is raised during execution of said host application code as a result of attempted access to the selected memory page of host application code if and only if said security or access rights check is satisfied by said at least one stub routine.
 2. The method as claimed in claim 1 wherein emulating the translated executable code of the selected memory page further includes receiving an authentication from a digital rights management subsystem.
 3. The method as claimed in claim 1 further including setting up an exception handler to receive execution control when the exception is raised.
 4. The method as claimed in claim 3 further including executing the exception handler when the exception is raised.
 5. The method as claimed in claim 1 further including waiting for the exception to be raised.
 6. The method as claimed in claim 1 wherein translating the executable code of the selected memory page of host application code further includes transforming a portion of the host application code into another code interpretable by an emulator.
 7. The method as claimed in claim 1 wherein selecting a memory page of host application code includes selecting a memory page that contains functions which are not executed more than a minimal number of times to avoid system performance degradation.
 8. The method as claimed in claim 1 further including wrapping the host application code with stub code of the stub code area.
 9. The method as claimed in claim 1 wherein a code block from the host application code is selected via a hardware mechanism.
 10. An article of manufacture comprising a non-transitory machine-accessible medium including instructions that, when executed by a machine, cause the machine to be operable to: select a memory page of host application code; translate executable code of the selected memory page of host application code; move the translated executable code of the selected memory page from the host application into a stub code area comprising at least one stub routine for performing any of a security and access rights check; overwrite the selected memory page of host application code; remove host page permission for execution of code in the selected memory page of host application code; and emulate the translated executable code of the selected memory page that was moved into the stub code area when an exception is raised during execution of said host application code as a result of attempted access to the selected memory page of host application code if and only if said security or access rights check is satisfied by said at least one stub routine.
 11. The article of manufacture as claimed in claim 10 wherein emulating the translated executable code of the selected memory page being further operable to receive an authentication from a digital rights management subsystem.
 12. The article of manufacture as claimed in claim 10 being further operable to set up an exception handler to receive execution control when the exception is raised.
 13. The article of manufacture as claimed in claim 12 being further operable to execute the exception handler when the exception is raised.
 14. The article of manufacture as claimed in claim 10 being further operable to wait for the exception to be raised.
 15. The article of manufacture as claimed in claim 10 being further operable to transform a portion of the host application code into another code interpretable by an emulator.
 16. The article of manufacture as claimed in claim 10 being further operable to select a memory page that contains functions which are not executed more than a minimal number of times to avoid system performance degradation.
 17. The article of manufacture as claimed in claim 10 being further operable to wrap the host application code with stub code of the stub code area.
 18. The article of manufacture as claimed in claim 10 wherein a code block from the host application code is selected via a hardware mechanism. 